DE1772853A1 - Motion picture camera with electromagnetic release device - Google Patents

Description

1 7 7 "7

NIEZOLDI & KRÄMER GIiBH, 3 Hünchen 38,

Hirschgartenallee

German Patent Office

8 Munich 2
Zweibrückenstrasse 12

N 07/68

New patent application Gög / Wuf July 11, 1968

Niezoldi & Krämer GmbH, 8 Munich

Motion picture camera with electromagnetic release device

The invention relates to a motion picture camera with a release device, which comprises a trigger member actuated by a control magnet, which in its rest position | locks the camera drive and opens the motor circuit, and that of the control magnet as a result of the actuation of the Release button of the camera in its operating position which releases the camera drive and closes the motor circuit is brought.

Such a camera has the advantage that the remote release by means of an electrical supply cable and easier Pushbutton can be made instead of the cable release that was previously used, designed as a Bowden cable. Another advantage of such a camera is that it can be used for several types of drive without too great a drive effort usable to machon.

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The disadvantage here is the relatively high power consumption by the control magnet and the camera drive.

It is the object of the invention to remedy this disadvantage.

This is achieved with the camera according to the invention in that its triggering device has a of the control magnet is assigned current-controlling acting timing element.

It is advantageous to shunt the timing element in series with the exciter winding of the control magnet To lay drive motor. When the camera is put into operation, the control magnet is then activated with its pull-in current of the company is only supplied with its much smaller holding current.

If the camera is equipped with an electronic trigger, which can be switched on in its excitation circuit when the camera is used for several operating modes ψ with regard to an optimal use of space, especially with amateur cameras - combined with the requirement for the least possible wear and tear The advantage that the timing element is part of a transistor unit located between the release button and the control magnet, acting as an electronic shutter release for the camera, and a transistor stage associated with this unit and switching the excitation circuit of the control magnet is connected upstream or downstream in such a way that the operating point is in the input or output characteristic field this transistor stage - reducing the excitation current - shifts.

The subject matter of the invention is shown below with reference to the drawing in one of several types of execution Embodiment explained. Show it

BATH ORIGINAL

1 shows a view of the release device with an electromagnetically controlled release element,

2 shows an excitation circuit of the camera,

Fig. J5 shows the circuit of an electronically operating Trigger of the release device,

4 shows a variant of FIG. J5.

In Fig. 1, an electric direct current motor 1 is arranged as the drive motor of a motion picture camera, the shaft 2 of which drives a shaft 5, the main gear shaft of the camera, which is fixedly mounted on the device via a reduction gear 3> 4. This main gear shaft 5 carries the rotary shutter, not shown, and controls the film switching mechanism of the camera for transporting the film strip in a manner known per se. A stop wheel 6 is attached to it, which interacts with a release element 7, which is designed here as a double-armed lever with lever arms 7.1 and 7.2 that can be pivoted about an axis 8 fixed to the device. The release member 7, which is under the action of a tension spring 9, is provided with a nose 10 which, when the drive is idle, engages in a cutout 11 of the stop wheel and locks the main gear shaft 5 in a position precisely defined by the release member 7. When the camera is in operation, the magnetic field effect of the current-carrying coil of a control magnet 12 causes the release element ¹ J to move into its position shown in dashed lines in FIG 5 releases.

In the circuit of the drive motor fed by a source 15 1 in Figure 2, the control magnet 12 'is in series to a parallel connection of the drive motor 1 and a capacitor 16 as a timing element. The drive motor circuit is also here at the same time the circuit of the control magnet. This excitation circuit of the camera is activated during commissioning

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closed by a push button switch 17. ^N

At the moment of switching on the maximum excitation current flows, which is only due to the winding resistance of the control magnet 12 is limited as the current of the control magnet; the motor is de-energized because of the uncharged timing element 16. As a result of the increase in the DC resistance of the timer 16 xtföhrend the charging process begins increasing current flow through the drive motor 1, but the excitation current through the entire circuit drops. Is the The charging process at the timer 16 ends, the minimum exciter current flows through the entire circuit, which is now also full flows through the motor and still has to be so large that the holding current of the control magnet 12 is not exceeded once and on the other hand the engine torque generated by it will overcome the lactmonent of the drive engine 1 and can set the motor in motion.

The greatest field force of the control magnet 12 thus occurs when Switching on the arrangement, so that by the advantageously occurring start-up delay of the drive motor 1 the The nose 10 of the release member 7 is pivoted out of the cutout 11 of the stop wheel 6 and thus the main transmission shaft 5 is released before the drive motor 1 starts up. It is a further advantage of this arrangement that the parallel connection of the timing element 16 with the drive motor 1 the strong current impulse surge is avoided, which is known when switching on a DC motor with full voltage because of the lack of induction voltage as a counter voltage occurs.

In the exemplary embodiment in Fig. ') , The circuit of a drive motor 13, in contrast to Fig. 2, is parallel to the circuit of a control magnet 19. The drive motor Iu is connected to one of the two circuits via a switch 21 controlled by the control magnet 19 and acting as a normally open contact

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ingenious source 20 switched. See the control magnet 19 and the release button 22 is a transistor unit 23, which acts as an electronic shutter release for the camera works.

In the exemplary embodiment, this transistor unit 25 consists of an electronic switch which is essentially formed from two transistors 25 and 2β of the same type, with the emitter of transistor 25 directly and the emitter of transistor 26 via the trigger button on the positive pole of source 20 for pnp types lie, and the collector of transistor 25 is switched to the base of transistor 26 % switched . The transistor 25 is continuously connected to the voltage of the source 20 and, when the arrangement is idle, is conductive due to the base potential held by the resistor 29. When the transistor 25 is conductive, the base of the following transistor 26 is so strongly positive that it blocks in the idle state. When the release button 22 is pressed, the full positive potential of the source 20 is applied directly to the base of the transistor 25, the base-emitter voltage is thus zero and the transistor 25 blocks. As a result, the base potential of the transistor 26 becomes negative and so large that the transistor 26 becomes conductive and thus closes the excitation circuit of the control magnet I9. Since |

the collector of the transistor 26 is directly on the control magnet 19, the full current also flows from the positive pole the source 20 via the emitter-collector path of the transistor 26 and the control magnet 19 * which is now the mechanical The camera drive is locked and via its work contact 21 turns on the drive motor 18. This state continues as long as the release button 22 is pressed. A timer is connected between terminals 31 and 32 33 * consisting of a resistor 3 ^ · and a capacitor 35 after Fir ,. 3a # so is at the first moment of switching on / i when the trigger button 22 is pressed, the Banis emitter

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Voltage and thus also the collector-emitter current of the transistor 25 of the uncharged capacitor 35 because of almost zero. The full current then flows from the source 20 via the emitter-collector path of the transistor 26 through the electromagnet 19 * as described above. The direct current resistance value of the timing element 33 rises steadily during the charging of the capacitor 35 until its maximum value, namely the value of the resistance j> k, is reached when the charging process is completed. This also increases the base-emitter voltage and thus the collector current of the transistor 25. By increasing the collector current flow of the transistor 25, the base potential of the transistor 26 is shifted towards positive values and the current flow through the emitter-collector path of the Transistor 26 and the control magnet 19 is reduced. The base voltage divider of the transistor 25 from the timing element 33 and the resistor 29 should be dimensioned so that the collector current through the transistor 26 does not fall below the minimum value of the holding current of the control magnet 19 when the charging process on the capacitor 35 is completed.

According to Fig. 3b instead of the timer 33 between the Terminals 31 and 32 in Pig. 3a between the terminals 36 and 37 a timer 38 is switched. The timer 38 consists of a resistor 39 and a capacitor 40 and is in addition to the winding resistance of the electromagnet 19, the DC output resistance of the transistor 26 when pressing the release button 22 therefore occurs in the switch-on trnoment a maximum collector current occurs due to the uncharged capacitor 40, while at the end of the * - Charging process on the capacitor 4o a minimal current flow of the source 20 via the emitter-collector path of the transistor 26 and the resistor 39 through the control magnet 19 sets.

Pig. 3c as an alternative to Pig. 3a and 3b

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extendedos timing element 4l, which consists of a series element with Resistor 42, capacitor 43 and a variable Resistance 44 exists and between terminals 45 and 46 is switched. Is when the shutter button 22 is pressed Transistor 25 blocked, the timing element 4l because of of the uncharged capacitor 43 has its smallest DC resistance value on] the base-emitter voltage and thus also the collector current of the transistor 26 reach their maximum values. The increases during the charging process DC resistance of the timer 41 until it reaches the value of the resistor 44 when the capacitor 43 is charged Has. But then the base of the transistor 26 also takes its ™ largest positive potential, so that the base-emitter voltage and the collector, stroni of transistor 26 theirs achieve minimum values.

In FIG. 4, the transistor unit 23 in FIG. 3 is expanded by a transistor 4o in a common base circuit between the terminals 36 and 37. If transistor 26 becomes conductive when the release button 22 is pressed, the emitter of transistor 43 receives positive potential. The transistor 48 also becomes conductive. A non-charged capacitor 49 on the 13asiD of the transistor 43 lowers the B-sis to a negative potential, so that the full Kollektorstrorn via the transit sistor g 43 flows through the electromagnet 19th While the capacitor 49 is charging, the base potential is raised more and more positively until, when the charging process is completed, the base-emitter voltage of the transistor 48 is only slightly int and consequently only a slight collector current flows through the control magnet 19, which, however, is greater than the minimum holding current of the control magnet.

When the release mechanism 22 is released, the capacitor discharges 49 over resistor 50 and Dio <jo 51, resistor 52 and the Winding resistance of the control magnet 19.

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Claims (2)

Claims 1. Motion picture camera with a release device, which a includes actuated by a control magnet trigger member which locks the camera drive in its rest position and the motor circuit opens, and that of the control magnet as a result of the actuation of the shutter button of the camera in his the camera drive and the motor circuits shooting boom position is brought, thereby gekennzei chnet that the tripping device has a currentstoucrnd on the excitation circuit of the oteuermagneten acting timer is assigned. 2. Camera according to claim 1, characterized gekennzei chnet that the timer is shunted to the connected in series with the excitation winding of the control magnet Drive motor lies. J5. Camera according to claim 1, characterized in that that the timing element is part of a lying between the release button and the control magnet, as an electronic one Trigger of the camera acting transistor unit and one of this unit associated, the excitation circuit of the oteuermagneten switching transistor stage is connected upstream or downstream in such a way that the operating point in the input or output characteristic field of this transistorctufc - reducing the excitation current - shifts. 10982A / 0469 BAO ORiGIMAL